Crystallization trial is one of the most important but time-consuming steps in macromolecular crystallography. Once a crystal appears in a certain crystallization condition, the crystal is typically harvested from the crystallization drop, soaked into a cryoprotection buffer, flash-cooled with a liquid nitrogen or cold gas flow and finally evaluated its diffraction quality by an X-ray beam. During these long process, crystal may be damaged and the result from the diffraction experiment does not necessarily reflect a nature of the crystal. On in-situ diffraction experiment, where a crystal in a crystallization drop is directly irradiated to an X-ray beam, a diffraction image from a crystal without any external factors such as harvesting and cryoprotection and, as a result, a nature of crystal can be evaluated quickly. In the Photon Factory, a new table-top diffractometer for in-situ diffraction experiments has been developed. It consists of XYZ translation stages with a plate handler, on-axis viewing system with a large numeric aperture and a plate rack where ten crystallization plates can be placed. These components sit on a common plate and it is placed on the existing diffractometer table in the beamline endstation. The CCD detector with a large active area and a pixel array detector with a small active area are used for acquiring diffraction images from crystals. Dedicated control software and user interface were also developed. Since 2014, user operation of the new diffractometer was started and in-situ diffraction experiments were mainly performed for evaluations of crystallization plates from a large crystallization screening project in our facility. BL-17A [1], one of micro-focus beamlines at the Photon Factory, is planned to be upgraded in March 2015. With this upgrade, a new diffractometer, which has a capability to handle a crystallization plate, will be installed so that diffraction data sets from crystals in crystallization drop can be collected.

Single-wavelength anomalous dispersion (SAD) experiment with light atoms as anomalous scatterers has been carried out using longer wavelengths up to 2.3 Å. We have been developing a synchrotron beamline dedicated to the SAD experiments where wavelengths longer than 2.7 Å are available to enhance weak anomalous signals. Larger background noise due to the longer wavelength, which is one of the major problems in the experiment, is reduced by introducing a standing helium chamber surrounding both the whole diffractometer and the X-ray detector. The system allows to perform experiments with normal and long waveldngths under the same environment. Helium cold stream is fed into the chamber at the sample position and reused after removing contaminants to keep the temperature of the stream at 30 K or below economically. Capillary-top-mount method [1] was improved to further reduce the background noise and to accommodate with smaller or needle-shape crystals. Several results on de-novo structural solutions with sulfur-SAD phasing will be reported in addition to the current performance of the beamline and its future plan.